copyright ©2011 brooks/cole, cengage learning estimating means with confidence chapter 12
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Copyright ©2011 Brooks/Cole, Cengage Learning
Estimating Means
with Confidence
Chapter 12
Copyright ©2011 Brooks/Cole, Cengage Learning 2
11.1 Introduction to CI for Means• A parameter is a population characteristic – value
is usually unknown. We estimate the parameter using sample information.
• A statistic, or estimate, is a characteristic of a sample. A statistic estimates a parameter.
• A confidence interval is an interval of values computed from sample data that is likely to include the true population value.
• The confidence level for an interval describes our confidence in the procedure we used. We are confident that most of the confidence intervals we compute using a procedure will contain the true population value.
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More Estimation Situations
Situation 1. Estimating the mean of a quantitative variable.
Example research questions:
What is the mean time that college students watch TV per day? What is the mean pulse rate of women?
Population parameter: (spelled “mu” and pronounced “mew”) = population mean for the variable
Sample estimate: = the sample mean for the variablex
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More Estimation Situations
Situation 2. Estimating the population mean of paired differences for a quantitative variable.
Example research questions:
What is the mean difference in weights for freshmen at the beginning and end of the first semester? What is the mean difference in age between husbands and wives in Britain?
Population parameter: d = population mean of the differences in the two measurements
Sample estimate: = the mean of the differences for a sample of the two measurements
d
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Situation 3. Estimating the difference between two populations with regard to the mean of a quantitative variable.
Example research questions:How much difference is there in average weight loss for those who diet compared to those who exercise to lose weight? How much difference is there between the mean foot lengths of men and women?
Population parameter: 1 – 2 = difference between the two population means.
Sample estimate: = difference between the two sample means.
More Estimation Situations
21 xx
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Paired Data
Paired data (or paired samples): when pairs of variables are collected. Only interested in population (and sample) of differences, and not in the original data.
• Each person measured twice. Two measurements of same characteristic or trait are made under different conditions.
• Similar individuals are paired prior to an experiment. Each member of a pair receives a different treatment. Same response variable is measured for all individuals.
• Two different variables are measured for each individual. Interested in amount of difference between two variables.
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Independent SamplesTwo samples are called independent samples when the measurements in one sample are not related to
the measurements in the other sample.
• Random samples taken separately from two populations and same response variable is recorded.
• One random sample taken and a variable recorded, but units are categorized to form two populations.
• Participants randomly assigned to one of two treatment conditions, and same response variable is recorded.
• Two random samples taken from a population and a separate variable is measured in each sample..
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Standard Errors
Rough Definition: The standard error of a sample statistic measures, roughly, the average difference between the statistic and the population parameter. This “average difference” is over all possible random samples of a given size that can be taken from the population.
Technical Definition: The standard error of a sample statistic is the estimated standard deviation of the sampling distribution for the statistic.
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Poll: Class of 175 students. In a typical day, about how much time to you spend watching television?
Standard Errors of a Sample Means
Example 11.2 Mean Hours Watching TV
diffs paired of dev std sample ,).(.
deviation standard sample ,).(.
dd sn
sdes
sn
sxes
Variable N Mean Median TrMean StDev SE Mean
TV 175 2.09 2.000 1.950 1.644 0.124 124.
175
644.1..
n
sxes
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Study: n1 = 42 men on diet, n2 = 27 men on exercise routine
Standard Error of the Difference Between Two Sample Means
Example 11.3 Lose More Weight by Diet or Exercise?
2
22
1
21
21 ).(.n
s
n
sxxes
Diet: Lost an average of 7.2 kg with std dev of 3.7 kgExercise: Lost an average of 4.0 kg with std dev of 3.9 kg
So, kg 2.30.42.721 xx
81.0
47
9.3
42
7.3).(. and
22
21 xxes
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Using Student’s t-Distribution to Determine the Multiplier
t* multiplier: value in a t-distribution with df = n – 1 such that the area between
-t* and +t* equals the desired confidence level.
t-distribution: bell shape, centered at 0, more spread out than standard normal curve from using s, instead of .
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Lesson 1: Finding a CI for a Mean for Any Sample Size and Any Confidence Level
Sample estimate Multiplier Standard error
Sample estimate: = sample mean
Standard error:
t-interval: where df = n – 1 for the multiplier t*.
11.2 CI Module 3: Confidence Intervals for One Population Mean
n
sxes ..
x
n
stx *
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Conditions Required
Situation 1: The population of the measurements is |bell-shaped, and a random sample of any size is measured. In practice, for small samples, the data should show no extreme skewness and should not contain any outliers.
Situation 2: The population of measurements is not bell-shaped, but a large random sample is measured. A somewhat arbitrary definition of a “large” sampleis n ≥ 30, but if there are extreme outliers, it is better to have an even larger sample size than n = 30.
Two Situations t-interval is Valid:
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Example 11.5 Mean Forearm Length
Data: Forearm lengths (cm) for a random sample of n = 9 men
25.5, 24.0, 26.5, 25.5, 28.0, 27.0, 23.0, 25.0, 25.0
Note: Dotplot shows no obvious skewness and no outliers.
95% Confidence Interval: 25.5 2.31(.507) 25.5 1.17 24.33 to 26.67 cm
507.9
52.1.. and ,52.1 ,5.25
n
sxessx
Multiplier t* from Table A.2 with df = 8 is t* = 2.31
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Calculating a Confidence Interval for a Population Mean
t-interval:
1.Make sure appropriate conditions apply checking sample size and/or a shape picture. For small samples (n < 30) with extreme skewness or outliers, you cannot proceed.2.Choose a confidence level.3.Compute the sample mean and standard deviation.4.Calculate the standard error of the mean.5.Calculate df = n – 1 6.Use Table A.2 (or software) to find the multiplier t*.
n
stxxestx ** ..
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Example 11.6 Watching TVPoll: Class of 175 students. In a typical day, about
how much time to you spend watching television?
The sample mean was 2.09 hours and the sample standard deviation was 1.644 hours. 124.
175
644.1..
n
sxes
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Example 11.6 Watching TV
Note: the 99% CI estimate is wider than the 95% one.
A 95% Confidence Interval: 2.09 1.98(.124) 2.09 .25 1.84 to 2.34 hours
A 99% Confidence Interval: 2.09 2.63(.124) 2.09 .33 1.76 to 2.42 hours
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Example 11.6 Watching TV
Correct Interpretation of a CI for a Mean
We don’t know whether or not the mean TV viewing hours for Penn State students is really between 1.84 to 2.34 hours.
•It is if we got one of the 95% of possible samples for which the sample mean is close enough to the true population mean for our procedure to work.
•It isn’t if we happened to get one of the 5% of possible samples for which the sample mean is too far away from the population mean for the procedure to work.
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Example 11.6 Watching TV
A Common Misinterpretation of a CI for a Mean
•We can be fairly certain that the population mean forearm length is covered by this interval. •This does not give us any information about the range of individual forearm lengths. •Do not fall into the trap of thinking that 95% of men’s forearm lengths are in this interval.
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Example 11.7 What Students Sleep More? Q: How many hours of sleep did you get last night,
to the nearest half hour?
Note: Bell-shape was reasonable for Stat 10 (with smaller n).
Notes: Interval for Stat 10 is wider (smaller sample size)Two intervals do not overlap Stat 10 average significantly higher than Stat 13 average.
Class N Mean StDev SE MeanStat 10 (stat literacy) 25 7.66 1.34 0.27Stat 13 (stat methods) 148 6.81 1.73 0.14
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Lesson 2: Special Case: Approximate 95% Confidence Intervals for Large Samples
For sufficiently large samples, the interval
Sample estimate 2 Standard error
is an approximate 95% confidence interval for a population parameter.
Note: The 95% confidence level describes how often the procedure provides an interval that includes the population value. For about 95% of all random samples of a specific size from a population, the confidence interval captures the population parameter.
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Example 11.8 Watching TV
Article: with 95% confidence, the mean is between 1.8 and 2.3 hours.
Technically: We are 95% confident the interval from 1.842 to 2.338 hours is correct in that it captures the mean television viewing hours for Penn State students.
t-Interval: 2.09 1.98(.124) 2.09 .25 1.84 to 2.34 hours
Approximate 95% Confidence Interval: 2.09 2(.124) 2.09 .248 1.842 to 2.338 hours
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Data: two variables for each of the n individuals or pairs, use the difference d = x1 – x2
Population parameter: d = mean of the differences for the population
Sample estimate: = sample mean of the differences
Standard error:
CI for d: where df = n – 1 for the multiplier
t*
11.3 CI Module 4: CI for Population Mean of Paired Differences
n
sdes d..
d
destd ..*
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Data: two variables for n individuals or pairs; use the difference d = x1 – x2.
Population parameter: d = mean of differences for the population = 1 – 2.
Sample estimate: = sample mean of the differences
Standard deviation and standard error: sd = std dev of sample of differences;
Confidence interval for d: where df = n – 1 for the multiplier t*.
11.3 CI Module 4: CI for Population Mean of Paired Differences
destd ..*
n
sdes d..
d
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Conditions Required
Situation 1: The population of differences is |bell-shaped, and a random sample of any size is measured. In practice, for small samples, the differences in the sample should show no extreme skewness and should not contain any outliers.
Situation 2: The population of differences is not bell-shaped, but a large random sample is measured. A somewhat arbitrary definition of a “large” sample is n ≥ 30 pairs, but if there are extreme outliers in the sample of differences, it is better to have an even larger sample size than n = 30.
Two Situations t-interval is Valid:
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Example 11.9 Screen Time: Computer vs TV
Data: Hours spent watching TV and hours spent on computer per week for n = 25 students.
Note: Boxplot shows no obvious skewness and no outliers.
Task: Make a 90% CI for the mean difference in hours spent using computer versus watching TV.
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Example 11.9 Screen Time: Computer vs TV
90% Confidence Interval: 5.36 1.71(3.05) 5.36 5.22 0.14 to 10.58 hours
05.325
24.15.. and ,24.15 ,36.5
n
sdessd d
d
Multiplier t* from Table A.2 with df = 24 is t* = 1.71
Results:
Interpretation: We are 90% confident that the average difference between computer usage and television viewing for students represented by this sample is covered by the interval from 0.14 to 10.58 hours per week, with more hours spent on computer usage than on television viewing.
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Calculating a Confidence Interval for a Population Mean of Paired Differences
1.Make sure appropriate conditions apply checking sample size and/or a shape picture of the differences.2.Choose a confidence level.3.Compute the differences for the n pairs in the sample, then find the mean and std dev for the differences.4.Calculate the standard error of the mean difference.5.Calculate df = n – 1 6.Use Table A.2 (or software) to find the multiplier t*.
n
stddestd d ** ..
Lesson 1: The General (Unpooled) Case
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11.4 CI Module 5: CI for Difference in Two Population Means (Independent Samples)
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CI for Difference for the Difference between Two Population Means (Indep)
Approximate CI for 1 – 2:
where t* is the value in a t-distribution with area between -t* and t* equal to the desired confidence level. Approximate df difficult to specify. Use computer software or conservatively use the smaller of the two sample sizes and subtract 1.
Note: for an approximate 95% CI, use a multiplier of 2.
2
22
1
21*
21 n
s
n
stxx
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Degrees of Freedom
The t-distribution is only approximately correct and df formula is complicated (Welch’s approx):
Statistical software can use the above approximation, but if done by-hand then use a conservative df = smaller of n1 – 1 and n2 – 1.
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Necessary Conditions
Two samples must be independent and either:
Situation 1: Populations of measurements both bell-shaped, and random samples of any size are measured.
Situation 2: Large (n 30) random samples are measured. But if there are extreme outliers, or extreme skewness, it is better to have an even larger sample than n = 30.
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Example 11.11 Effect of a Stare on Driving
Randomized experiment: Researchers either stared or did not stare at drivers stopped at a campus stop sign; Timed how long (sec) it took driver to proceed from sign to a mark on other side of the intersection.
Task: Make a 95% CI for the difference between the mean crossing times for the two populations represented by these two independent samples.
No Stare Group (n = 14): 8.3, 5.5, 6.0, 8.1, 8.8, 7.5, 7.8, 7.1, 5.7, 6.5, 4.7, 6.9, 5.2, 4.7
Stare Group (n = 13): 5.6, 5.0, 5.7, 6.3, 6.5, 5.8, 4.5, 6.1, 4.8, 4.9, 4.5, 7.2, 5.8
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Example 11.11 Effect of a Stare on Driving
Checking Conditions:
Boxplots show …
• No outliers and no strong skewness.
• Crossing times in stare group generally faster and less variable.
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Example 11.11 Effect of a Stare on Driving
The 95% confidence interval for the difference between the population means is 0.14 seconds to 1.93 seconds .
Note: The df = 21 was reported by the computer package based on the Welch’s approximation formula.
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Lesson 2: Equal Variance Assumption and the Pooled Standard ErrorMay be reasonable to assume the two populations have equal population standard deviations, or equivalently, equal population variances:
Estimate of this variance based on the combined or “pooled” data is called the pooled variance. The square root of the pooled variance is called the pooled standard deviation:
222
21
2
11 deviation standard Pooled
21
222
211
nn
snsnsp
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Pooled Standard Error
21
21
2
2
2
1
2
21
11
11
).(. Pooled
nns
nns
n
s
n
sxxes
p
p
pp
Note: Pooled df = (n1 – 1) + (n2 – 1) = (n1 + n2 – 2).
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Pooled Confidence Interval
Pooled CI for the Difference Between Two Means (Independent Samples):
where t* is found using a t-distribution with df = (n1 + n2 – 2) and sp is the pooled standard deviation.
21
*21
11
nnstxx p
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Example 11.14 Male and Female Sleep Times
Data: The 83 female and 65 male responses from students in an intro stat class.
Note: We will assume equal population variances.
Task: Make a 95% CI for the difference between the two population means sleep hours for females versus males.
Q: How much difference is there between how long female and male students slept the previous night?
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Example 11.14 Male and Female Sleep Times
Notes:• Two sample standard deviations are very similar.• Sample mean for females higher than for males.• 95% confidence interval contains 0 so cannot rule out
that the population means may be equal.
Two-sample T for sleep [with “Assume Equal Variance” option]
Sex N Mean StDev SE MeanFemale 83 7.02 1.75 0.19Male 65 6.55 1.68 0.21
Difference = mu (Female) – mu (Male)Estimate for difference: 0.46195% CI for difference: (-0.103, 1.025)T-Test of difference = 0 (vs not =): T-Value = 1.62 P = 0.108 DF = 146Both use Pooled StDev = 1.72
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Example 11.14 Male and Female Sleep Times
Pooled standard deviation and pooled standard error “by-hand”:
72.1957.2
26583
68.116575.1183
2
11 dev std Pooled
22
21
222
211
nn
snsnsp
285.065
1
83
172.1
11).(. Pooled
2121
nn
sxxes p
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Pooled or Unpooled?
• If the larger sample size produced the larger standard deviation, the pooled procedure is acceptable because it will be conservative.
• If the smaller standard deviation accompanies the larger sample size, the pooled test can be quite misleading and not recommended.
• If sample sizes are equal, the pooled and unpooled standard errors are equal. Unless the sample standard deviations are quite similar, it is best to use the unpooled procedure.
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Example 11.15 Male and Female Sleep Times
Note: Unpooled s.e. is 0.30 while pooled s.e. is 0.36 (larger).
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Confidence Interval for the Difference in Two Population Means
1.Make sure appropriate conditions apply checking sample size and/or a shape picture of the differences.2.Choose a confidence level.3.Compute the mean and std dev for each sample.4.Determine whether the std devs are similar enough to pooled procedure can be used.5.Calculate the appropriate standard error (pooled or unpooled).6.Calculate the appropriate df.7.Use Table A.2 (or software) to find the multiplier t*.
21*
21 .. xxestxx